JPS61246009A - Continuous manufacture of fiber reinforced concrete plate - Google Patents

Abstract

A method for the continuous production of plates and/or shaped bodies of fibre reinforced hydraulic setting masses is described in which the mass is provided in a predetermined thickness over the entire width of the plate to be produced, on a substrate continuously moved by a belt. Fibre cuttings from a cutting device are dispersed in a desired distribution onto the surface of the mass moving with the substrate and these are subsequently incorporated into the mass by a tool acting uniformly over the entire width of the mass. The raw plate can be further processed in its still deformable condition and brought into a desired final shape.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a method for continuously manufacturing plates or plate shaped bodies from fiber-reinforced hydraulic rings.

(Prior Art and Problems) Manufacturing fiber-reinforced concrete plates and their shaped bodies is not only very difficult, but also has many problems.

With traditional spraying methods, the fibers are as desired (not necessarily homogeneous)
It is extremely difficult to achieve a uniform plate thickness with a uniform distribution. Furthermore, during molding and shaping of the green plate, the hydraulic ring tends to adhere to the mold surface, making molding and mold release difficult.

OBJECTS OF THE INVENTION It is an object of the present invention to provide a fiber-reinforced plate of uniform thickness with a desired amount of fibers in a desired distribution or orientation, and a series of plate shaped bodies with uniformly smooth reinforcing (if desired) surfaces. The purpose is to provide a manufacturing method.

(Summary of the Invention) The above object is to form a hydraulic ring to a desired thickness on a substrate that moves along with the belt, and to cut fiber pieces cut by a cutter onto a continuously moving mass surface. This is achieved by the inventive method of compressing with a tool which dispenses a predetermined amount into the matrix during movement and simultaneously acts on the entire machining width.

(Effects of the Invention) The advantages of the above method are that in addition to being capable of continuous operation, it is also possible to form a hydraulic ring with a uniform thickness over the processing width;
The advantage is that it can be reinforced with fibers if desired.

In addition, since it does not contain excess water, it is possible to use a hydraulic ring that does not require dehydration.

The desired fiber distribution and orientation can be easily controlled and monitored, ensuring plate uniformity, which is difficult to obtain.

The substrate can also be used to provide a plate surface that is clean, smooth and, if desired, colored or textured or carved.

A particular advantage of the method of the invention is that during the manufacturing process, the side edges of the plate can be straightened by folding the edges of the substrate over the green plate edge of the uncured mass and rounding its corners.

This eliminates the need for edging, regardless of the state of the plate (raw state or hardened state).

In addition, the plate width can be adjusted from the beginning using the narrow section tolerance, and there is no need to straighten the plate, which usually results in material loss. The width adjustment is effected by adjustable fixed guide elements which are arranged at desired intervals on the belt and which move relative to the belt.

The substrate, which rests on the belt and moves relative to it, serves as a separating layer and forms the lateral edges of the plate, and can be composed of various materials, such as plastic foil, glass fleece or plastic-coated paper.

By using a substrate, the plate surface can be colored and textured, opening up many possibilities. Also.

The substrate can be used as a frame and can be removed from the plate surface without any residual parts or damage.

In this way, the plate surface will be completely uniform and smooth, without any rough spots or scratches.

Alternatively, the substrate itself or its reinforcing coating can also be fitted onto the plate surface.

Thus, a flat plate surface or a corrugated or trapezoidally shaped plate surface can be configured as desired in the raw green plate or other shaped bodies such as tubes.

Additionally, the substrate protects the finished plate during stacking and transportation. Since the substrate remains on the plate and acts similarly to post-processing, the expensive post-processing required in conventional methods can be omitted.

(Example) Next, details of the method of the present invention will be explained with reference to Examples.

On a continuously moving belt with guide elements arranged according to the desired width of the plate to be produced.

Install a board to receive the lump. The width of this substrate is preferably greater than the predetermined width of said play 1-, which is determined by the spacing of the guide elements, so that the edge areas of the longitudinal sides of the support protrude sufficiently to overlap the upper sides of the guide elements.

While the substrate advances with the belt, the hydraulic ring is continuously applied to the substrate with a uniform thickness and with a predetermined width depending on the guide element spacing. In this case 1, for example, the product to be manufactured
This is carried out by extruding a hydraulic ring from a nozzle having an opening corresponding to the width of the nozzle.

A cutting device is disposed above the hydraulic ring conveyance path at the rear of the extruder, and fiber pieces of a desired length are continuously discharged, passed through the gravity shoe 1-, and from there, they are scattered on the mass surface. It spreads out and gives direction.

Since the mass is continuously moving below a large number of sections, the fiber sections coming from the gravity chute are freely and evenly distributed over the surface of the mass.

In a further preparation layer, the fiber sections are forced into or mixed into the mass surface with a tool that acts over the entire mass surface.

In this case, by adjusting the tool, the mixing depth can be adjusted, so that the fiber distribution in the cross section of the plate can be selected according to the requirements.

At the same time, the sections are wetted and compress the mass.

Flexible tools are useful.

The fiber incorporation step is repeated multiple times in the same hydraulic mass layer on the substrate, or in sequentially applied hydraulic mass layers. In addition to reinforcing with fiber sections, endless fibers can be applied or embedded (in a known manner) in the play 1 to mass.

As mentioned above, the substrate is wider than the plate, and in order to pull up the parts of the board that protrude from the plate on both sides and cover the edges of the plate, the outer parts of said parts can be guided by sliding on the guide elements. Prevents rubbing of the hydraulic ring on the element and lateral binding.

Fold the protruding part of the board over the side edge of the raw plate and roll it neatly.

Dispense cement onto the top surface of the finished green plate or
Alternatively, a coating, such as a fleece, or a removable foil, which remains connected to the plate, can be provided.

According to the method of the invention, the outer surface of the finished plate can be treated, such as by coloring or engraving, and in other ways.
Properties can be strengthened or improved.

For this purpose, a peelable colored layer, engraving band or other reinforcing material is installed on the free side of the substrate, and in the case of a colored layer or other material layer, it is fitted into a hydraulic ring extruded on the substrate. In the case of a stamped strip, the plate surface is reinforced by coloring, engraving, or some other method by press-fitting the stamp into the hydraulic ring.

Therefore, no post-treatment of the plate surface is required.

According to the method of the present invention, a fiber-reinforced hydraulic ring that does not contain unnecessary water can be used. Either leave the green plate to harden as a flat plate, or put it into a shaping device as appropriate and shape it.6 To facilitate fiber incorporation and shaping, addi- tives can be used to optimize softness and tackiness. , which modifies the hydraulic ring by applying vibration.

The fibers can be distributed by suitably shaping the gravity chute or by providing fixed or driven elements within the gravity chute. Depending on the fiber length, dimensioning the gravity chute opening changes the desired orientation of the fibers.

A flexible fiber entrainment tool can be engaged with multiple parallel cutters within a hydraulic boundary, and the inherent elasticity of the material required for manufacture allows for the application of the desired spring force.

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Claims (12)

[Claims] (1) A method for continuously manufacturing a fiber-reinforced hydraulic mass plate or a shaped body thereof, in which the hydraulic mass is formed to a predetermined thickness on a substrate that moves along with the belt, and A fiber-reinforced concrete plate characterized in that a predetermined amount of incoming fiber sections are distributed on the surface of a continuously moving lump, and while the fiber pieces are being moved, they are pressed into the lump and at the same time the said lump is compressed with a tool that acts on the entire machining width. Continuous manufacturing method. (2) The fiber-reinforced concrete plate according to claim (1), characterized in that the fiber pieces are applied to a gravity chute so that they are scattered toward the mass and oriented in a desired direction. continuous manufacturing method. (3) The fibers according to claim 1, characterized in that by using a flexible tool, the fiber sections are gently introduced into the mass to achieve the desired distribution. Continuous manufacturing method for reinforced concrete plates. (4) A series of fiber-reinforced concrete plates according to claim 1, characterized in that endless fiber bundles are additionally added to the surface of the mass and drawn into the mass reinforced with fiber sections. Production method. (5) The continuous production method of fiber-reinforced concrete plates according to claim (1), wherein the lump contains only enough water for hydration. (6) The continuous manufacturing method of a fiber-reinforced concrete plate according to claim (1), characterized in that the hydraulic mass is extruded onto the substrate to a predetermined thickness. (7) The continuous manufacturing method of fiber-reinforced concrete plates according to claim (1), characterized in that the step of dispersing and press-fitting the fiber pieces into the continuously moving mass is repeated two or more times. (8) The continuous manufacturing method of fiber-reinforced concrete plates according to claim (1), characterized in that the dispersed press-fitting step is carried out sequentially on stacked layers of continuously moving blocks. (9) Claim (1) characterized in that the substrate is wider than the plate to be manufactured, and a vertical edge protruding from the edge of the green plate is folded over the edge of the green plate. Continuous manufacturing method of fiber-reinforced concrete plates as described. (10) The continuous manufacturing method for fiber-reinforced concrete plates as set forth in claim (1), which comprises distributing cement and applying a film to the free side of the fiber-reinforced mass before hardening. (11) For the purpose of strengthening the plate surface or improving its properties, the agglomerate side of said substrate is provided with a finishing material layer consisting of a material that integrates with the hydraulic agglomerate surface on the substrate and separates it from said substrate; Claim No. 1 (1) characterized in that
) Continuous manufacturing method for fiber reinforced concrete plates as described in item 1. (12) The continuous manufacturing method for fiber-reinforced concrete plates according to claim (1), characterized in that the green plate before hardening is shaped into a final shape using an appropriate device.